Inverted metamorphic GaInAs solar cell grown by dynamic hydride vapor phase epitaxy.

We present an inverted metamorphic rear heterojunction ∼1.0 eV GaInAs solar cell deposited by dynamic hydride vapor phase epitaxy (D-HVPE) with high growth rate. This device uses a Ga_1−xIn_xP compositionally graded buffer (CGB) to bridge the lattice constant gap between the GaAs substrate and the Ga_0.71In_0.29As emitter layer. High-resolution x-ray diffraction and transmission electron microscopy confirm that the Ga_0.71In_0.29As emitter is grown lattice-matched to the in-plane lattice constant of the CGB with minimal generation of defects at the GaInAs/GaInP interface. The device contains a threading dislocation density of 2.3 × 10⁶ cm⁻², a level that enables high-performance minority carrier devices and is comparable to previously demonstrated GaInP CGBs grown by D-HVPE. The device exhibits an open-circuit voltage of 0.589 V under a one-sun AM1.5G illumination condition and a bandgap-voltage offset of 0.407 V, indicating metamorphic epitaxial performance nearly equal to state-of-the-art devices. We analyze the dark current of the device and determine that reducing recombination in the depletion region, which can be achieved by reducing the threading dislocation density and optimizing the device doping density, will improve the device performance. The CGB and device layers, comprising ∼8 μm of thickness, are grown in under 10 min, highlighting the ability of D-HVPE to produce high-quality metamorphic devices of all types with the potential for dramatically higher throughput compared to present technology. [ABSTRACT FROM AUTHOR]